Prof. Zlatan Aksamija was recently quoted in a Science Newsstory about why scientists are studying how 2-D materials such as graphene behave at high temperatures. In the February 13 edition of Science News, Aksamija said that commonly used silicon-based electronics are “hitting a brick wall” regarding how much smaller they can be manufactured, and that 2-D materials could be ideal for constructing the next generation of tiny devices:

Cameron and NETlab alum Ela’s work on the thermal boundary conductance between van der Waals atomic layers and substrates, with impact on device applications on graphene, MoS2 and related materials, was included in Highlights of 2017, section on Energy at the Nanoscale: http://iopscience.iop.org/journal/0957-4484/page/Highlights%202017

Our article will be free to read throughout 2018, offering unlimited access to the work.

Adithya’s recent work on “Thermoelectric Properties of Periodic Quantum Structures in the Wigner-Rode Formalism” has been accepted for publication in a special issue of the Journal of Physics: Condensed Matter. The article is available here: https://doi.org/10.1088/1361-648X/aaa110

Features

The book offers a unique perspective bridging the fields of nanoscale heat transfer and nanoelectronics.

It covers both fundamentals and applications from the perspectives of theory/simulation, experimental measurements, and device applications.

It brings together a unique group of leading experts on this topic

Summary

Heat in most semiconductor materials, including the traditional group IV elements (Si, Ge, diamond), III–V compounds (GaAs, wide-bandgap GaN), and carbon allotropes (graphene, CNTs), as well as emerging new materials like transition metal dichalcogenides (TMDCs), is stored and transported by lattice vibrations (phonons). Phonon generation through interactions with electrons (in nanoelectronics, power, and nonequilibrium devices) and light (optoelectronics) is the central mechanism of heat dissipation in nanoelectronics.

This book focuses on the area of thermal effects in nanostructures, including the generation, transport, and conversion of heat at the nanoscale level. Phonon transport, including thermal conductivity in nanostructured materials, as well as numerical simulation methods, such as phonon Monte Carlo, Green’s functions, and first principles methods, feature prominently in the book, which comprises four main themes: (i) phonon generation/heat dissipation, (i) nanoscale phonon transport, (iii) applications/devices (including thermoelectrics), and (iv) emerging materials (graphene/2D). The book also covers recent advances in nanophononics—the study of phonons at the nanoscale. Applications of nanophononics focus on thermoelectric (TE) and tandem TE/photovoltaic energy conversion. The applications are augmented by a chapter on heat dissipation and self-heating in nanoelectronic devices. The book concludes with a chapter on thermal transport in nanoscale graphene ribbons, covering recent advances in phonon transport in 2D materials.

The book will be an excellent reference for researchers and graduate students of nanoelectronics, device engineering, nanoscale heat transfer, and thermoelectric energy conversion. The book could also be a basis for a graduate special topics course in the field of nanoscale heat and energy.

As part of the UMass Summer ENGineering Institute (SENGI) for high school students, NETlab-ers Meenakshi, Arnab, and Prof. Aksamija taught a workshop on the principles of thermoelectric energy conversion. We all had loads of fun!